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  • 1
    Electronic Resource
    Electronic Resource
    U-Pb zircon age and Nd isotopic composition of granitoids, charnockites and supracrustal rocks from Heimefrontfjella, Antarctica (1991)
    Springer
    International journal of earth sciences 80 (1991), S. 759-777 
    Details
    ISSN: 1437-3262
    Source: Springer Online Journal Archives 1860-2000
    Topics: Geosciences
    Description / Table of Contents: Abstract Heimefrontfjella and Mannefallknausane, in Dronning Maud Land, Antarctica, comprise an amphibolite-facies terrain and a granulite terrain, separated by a major mylonite zone. The amphibolite terrain is made up of mafic to felsic metavolcanics and metasediments, intruded by granitoid plutons: the granulite terrain has supracrustal rocks with similar lithologies, intruded by felsic plutonic rocks that crystallized as charnockites. U-Pb zircon ages (conventional and ion microprobe) demonstrate that magmatic activity was confined to a relatively short interval between 1130 and 1045 Ma and was followed in the amphibolite terrain by metamorphism around 1060 Ma. Specific ages are as follows: metarhyolite in the amphibolite terrain, 1093 ± 38 Ma; granitoids in the amphibolite terrain, 1045 ± 9 Ma to 1107 ± 16 Ma, charnockites in the granulite terrain, 1073 ± 8 Ma to 1135 ± 8 Ma, metamorphic zircons in garnet amphibolite and a post-metamorphic pegmatite, both 1060 ± 8 Ma. Older zircons were found only in a metasediment which yielded discordant zircon fractions with207Pb/206Pb ages between ∼ 1250 and 1450 Ma, and in a granulite facies metaquartzite, which contained concordant zircons with the following ages: 1104 ± 5 Ma, 1215 ± 15 Ma, ∼ 1400 Ma, ∼ 1700 Ma, ∼ 2000 Ma. The youngest age is interpreted as the age of granulite metamorphism, the older ages as those of detrital zircons. A Sm-Nd mineral isochron age of the garnet amphibolite (960 ± 120 Ma) agrees within error with the U-Pb age of metamorphic zircons (1060 ± 8 Ma). Initial εNd values (T = 1.1 Ga) for 15 samples range from +4 to−4. The highest came from a metabasalt and two granitoids from Milorgfjella, the northern area; the lowest from the granulite-facies metasediment and from a charnockite, both from Vardeklettane, a nunatak in the south. The positive but subdued values preclude generation directly from depleted MORB-type mantle εNd ∼ + 6 to + 7 at 1.1 Ga) and indicate generation from a source containing older crustal material.
    Abstract: Résumé Les régions de Heimefrontfjella et Mannefallknausane situées dans le Dronning Maud Land en Antartique sont formées par deux zones principales à degrés métamorphiques différents: une à faciès amphibolitique et une autre à faciès granulitiques, séparées par une zone mylonitique. Des roches métavolcaniques à composition variant de basique à felsique ainsi que des roches d'origine sédimentaire composent la zone amphibolitique. Elles sont recoupées par des plutons granitiques. La zone granulitique est formée également par des roches d'origine volcanique et sedimentaire qui sont, elles, recoupées par des charnockites. Les mesures d'U-Pb sur zircons (utilisant la méthode conventionnelle et la microsonde ionique) montrent que l'activité magmatique s'est confinée à une période relativement courte entre 1130 Ma et 1045 Ma. Elle a été suivie par un métamorphisme, il y a 1060 Ma, dans la zone amphibolitique. De façon plus détaillée, les âges sont les suivants: dans la zone amphibolitique, rhyolite datée à 1093 ± 38 Ma, granitoïdes datés à 1045 ± 9 Ma et 1107 ± 16 Ma; dans la zone granulitique, charnockites datées entre 1073 ± 8 Ma et 1135 ± 8 Ma, zircons métamorphiques provenant d'une amphibolite à grenat datés à 1060 ± 8 Ma et pegmatite postmétamorphique datée à 1060 ± 8 Ma. Deux roches ont fourni des zircons donnant des âges plus anciens: un sédiment métamorphisé et un metaquartzite. Les âges207Pb/206Pb obtenus pour les fractions discordantes des zircons du metasediment varient entre 1250 et 1450 Ma alors que le metaquartzite contient des zircons concordants avec les âges suivants: 1104±5 Ma, 1215±15Ma, ∼1400 Ma, ∼1700 Ma et ∼2000 Ma. L'âge le plus jeune obtenu pour le métaquartzite est interprété comme représentant l'âge du métamorphisme granulitique alors que les âges plus anciens représentent les âges de zircons détritiques. Une isochrone Sm-Nd sur minéraux a été obtenue sur une amphibolite à grenat. Elle définit un âge de 960 ± 120 Ma qui correspond, aux erreurs près, à l'âge U-Pb des zircons métamorphiques (1060 ± 8 Ma). Les εNdinitiaux (T = 1,l Ga) obtenus pour 15 échantillons varient entre +4 et −4. Les valeurs les plus élevées ont été obtenues pour un basalte et deux granitoïdes de Milorgfjella situés dans la partie nord; les valeur εNd les plus faibles proviennent du métasédiment dans la zone granulitique et d'une charnockite. Ces deux échantillons se situent dans le nunatak Vardeklettane dans le Sud. Les εNd étant positifs mais toutefois plus faibles que la valeur du manteau appauvri à cette période (entre +6 et +7 à 1,1 Ma), une extraction directe du manteau ne peut être retenue et nous suggérons que la région source contenait du matériau crustal plus ancien.
    Notes: Zusammenfassung Die Gebiete um Heimefrontfjella und Mannefallknausane in Dronning Maud Land, Antarktis, bestehen aus amphibolith- und granulitfaziellen Grundgebirgskomplexen, die durch eine große Mylonitzone voneinander getrennt sind. Der amphibolithfazielle Komplex besteht aus mafisch bis felsischen Metavulkaniten und Metasedimenten, die von Granitplutonen intrudiert werden. Der Granulitkomplex enthält Suprakrustalgesteine ähnlicher Art, die von Charnockiten intrudiert werden. U-Pb-Alter, die mit der konventionellen Multikorn-Methode und an der Ionen-Mikrosonde an Einzelkörner bestimmt wurden, engen die magmatische Aktivität zwischen 1130 und 1045 Ma ein. Auf diese Periode folgte in dem amphibolithfaziellen Gebiet eine Regionalmetamorphose um 1060 Ma. Die Einzelalter sind wie folgt: in dem amphibolithfaziellen Komplex ergab ein Metarhyolith 1039 ± 38 Ma, während die Granitoide zwischen 1045 ± 9 Ma und 1107 ± 16 Ma variieren. In dem Granulitkomplex wurden die Charnockite auf 1073 ± 8 Ma bis 1135 ± 8 Ma datiert, während metamorphe Zirkone aus einem Granatamphibolith sowie aus einem posttektonischen Pegmatit identische Alter von 1060 ± 8 Ma ergaben. Ältere Komponenten wurden lediglich in einer Metasediment-Probe gefunden, die diskordante Zirkone mit207Pb/206Pb Altern zwischen ca. 1250 und 1450 Ma enthielt, sowie in einem granulitfaziellen Metaquarzit, in dem konkordante Zirkone die folgenden Alter ergaben: 1104 ± 5 Ma, 1215 ± 15 Ma, ∼1400 Ma, ∼1700 Ma, ∼2000 Ma. Das jüngste Zirkonalter aus dem Metaquarzit interpretieren wir als Zeitpunkt der Granulitmetamorphose, während die höheren Alter detritische Komponenten repräsentieren. Eine Sm-Nd Mineralisochrone für einen Granatamphibolith hat ein Alter von 960 ± 120 Ma, das innerhalb der experimentellen Fehler mit einem U-Pb-Alter von 1060 ± 8 Ma für metamorphe Zirkone übereinstimmt. Initiale εNd-Werte (T = l.1 Ga) für 15 Proben variieren zwischen +4 und -4. Die höchsten Werte wurden für einen Metabasalt und zwei Granitoide von Milorgfjella im nördlichen Arbeitsgebiet bestimmt. Die niedrigsten Werte stammen aus dem granulitfaziellen Metaquarzit und von einem Charnockit, beide aus Vardeklettane, einem Nunatak im Süden. Die leicht positiven Werte lassen eine juvenile Bildung der Wirtsgesteine aus einem MORB-ähnlichen Mantel (εNd ∼ + 6 bis + 7 um 1.1 Ga) nicht zu und deuten ein Ausgangsmaterial mit Komponenten älterer kontinentaler Kruste an.
    Type of Medium: Electronic Resource
    URL: http://dx.doi.org/10.1007/BF01803700
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  • 2
    Electronic Resource
    Electronic Resource
    Thermal erosion by komatiites at Kambalda (1986)
    [s.l.] : Nature Publishing Group
    Nature 324 (1986), S. 600-600 
    Details
    ISSN: 1476-4687
    Source: Nature Archives 1869 - 2009
    Topics: Biology , Chemistry and Pharmacology , Medicine , Natural Sciences in General , Physics
    Notes: [Auszug] GROVES et al1 have added a further twist to the continuing debate on thermal erosion by komatiite magma. This concept was introduced by Huppert et al.2'3 who argue that hot, low-viscosity komatiite lava flows turbulently and transmits heat efficiently to floor rocks. When the flow rate is high ...
    Type of Medium: Electronic Resource
    URL: http://dx.doi.org/10.1038/324600a0
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  • 3
    Electronic Resource
    Electronic Resource
    Bizarre geochemistry of komatiites from the Crixás greenstone belt, Brazil (1989)
    Springer
    Contributions to mineralogy and petrology 101 (1989), S. 187-197 
    Details
    ISSN: 1432-0967
    Source: Springer Online Journal Archives 1860-2000
    Topics: Geosciences
    Notes: Abstract Komatiite lava flows in the Crixás greenstone belt, Goiás, Brazil, have textures and volcanic structures typical of Archean komatiites, but are geochemically most unusual. The flows are porphyritic and massive, or layered with spinifex upper parts and olivine cumulate lower parts. MgO contents range from 18 to 40%. In such lavas, only olivine (and minor chromite) can have crystallized, but neither major nor trace elements fall on olivine control lines. In MgO variation diagrams, CaO and Sr fall on lines with slopes steeper than olivine control lines; SiO2, FeO, Na2O, K2O and Y show little systematic variation; Zr shows a large variation that does not correlate with MgO; and Al2O3 decreases markedly with decreasing MgO. The aberrant behaviour is highlighted by the REE (rare earth elements) in spinifex and olivine cumulate layers from three flows: in the spinifex layers, chondrite-normalized REE patterns are hump-shaped with maxima at Nd or Sm ((La/Sm)N=0.6, (Gd/Yb)N=1.6–2.3), whereas cumulate zones in the same flows have steadily sloping patterns, with LREE enriched relative to HREE ((La/Sm)N=1.3, (Gd/Yb)N=1.4). Neither normal magmatic processes acting during emplacement of the komatiites, nor thermal erosion and wall-rock assimilation can explain these effects, and we speculate that elements commonly thought of as “immobile” (e.g. Al, Zr, REE) migrated during hydrothermal alteration or metamorphism. A Pb-Pb whole rock isochron gave an age of 2,728±140 Ma and selected Sm-Nd analyses an apparent isochron age of 2,825±98 Ma (ɛNd≈0). The Pb-Pb age is believed to be the approximate time of emplacement. Interpretation of the Sm-Nd data is complicated by the evidence of mobility of REE.
    Type of Medium: Electronic Resource
    URL: http://dx.doi.org/10.1007/BF00375305
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  • 4
    Electronic Resource
    Electronic Resource
    Petrology of mafic lavas within the Onega plateau, central Karelia: evidence for 2.0 Ga plume-related continental crustal growth in the Baltic Shield (1998)
    Springer
    Contributions to mineralogy and petrology 130 (1998), S. 134-153 
    Details
    ISSN: 1432-0967
    Source: Springer Online Journal Archives 1860-2000
    Topics: Geosciences
    Notes: Abstract The Onega plateau constitutes part of a vast continental flood basalt province in the SE Baltic Shield. It consists of Jatulian-Ludikovian submarine volcanic, volcaniclastic and sedimentary sequences attaining in places 4.5 km in thickness. The parental magmas of the lavas contained ∼10% MgO and were derived from melts generated in the garnet stability field at depths 80–100 km. The Sm-Nd mineral and Pb-Pb whole-rock isochron ages of 1975 ± 24 and 1980 ± 57 Ma for the upper part of the plateau and a SHRIMP U-Pb zircon age of 1976 ± 9 Ma for its lower part imply the formation of the entire sequence within a short time span. These ages coincide with those of picrites in the Pechenga-Imandra belt (the Kola Peninsula) and komatiites and basalts in the Karasjok-Kittilä belt (Norway and Finnmark). Together with lithostratigraphic, chemical and isotope evidence, these ages suggest the derivation of the three provinces from a single large (∼2000 km in diameter) mantle plume. These plume-generated magmas covered ∼600,000 km2 of the Baltic Shield and represent a major contribution of juvenile material to the existing continental crust at 2.0 Ga. The uppermost Onega plateau lavas have high (Nb/Th)N = 1.4–2.4, (Nb/La)N= 1.1–1.3, positive ɛNd(T) of +3.2 and unradiogenic Pb-isotope composition (μ1 = 8.57), comparable with those of modern oceanic plume-derived magmas (oceanic flood basalt and ocean island basalt). These parameters are regarded as source characteristics. The lower sequences have (Nb/Th)N= 0.58–1.2, (Nb/La)N= 0.52–0.88 and ɛNd(T) =−2.6. They have experienced mixing with 10–30% of continental crust and resemble contaminated lavas from other continental flood basalt provinces. The estimated Nb/U ratios of 53 ± 4 in the uncontaminated rocks are similar to those found in the modern mantle (∼47) suggesting that by 2.0 Ga a volume of continental crust similar to the present-day value already existed.
    Type of Medium: Electronic Resource
    URL: http://dx.doi.org/10.1007/s004100050355
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  • 5
    Electronic Resource
    Electronic Resource
    Ore deposits associated with mafic magmas in the Kaapvaal craton (1997)
    Springer
    Mineralium deposita 32 (1997), S. 323-334 
    Details
    ISSN: 1432-1866
    Source: Springer Online Journal Archives 1860-2000
    Topics: Geosciences
    Notes: Abstract Mafic and ultramafic magmatism played an important role in the 3.5 Ga long history of the Kaapvaal craton. The oldest (3.5 Ga) greenstone belts contain mafic and ultramafic volcanics that erupted in an oceanic environment, probably in oceanic plateaus. Then followed a series of continental flood basalts, from the ∼3.4 Ga old Commondale and Nondweni sequences, to the 180 Ma Karoo basalts. The history was dominated, however, by the emplacement, 2.1 Ga ago, of the Bushveld complex, an enormous layered ultramafic-mafic-felsic intrusion. Three types of ore deposits might be found in such a sequence: Ni-Cu-Fe sulfides in komatiites of the greenstone belts; “Noril'sk-type” Ni-Cu-PGE deposits in the Karoo and other flood basalts; and deposits of Cr, platinum-group elements (PGE) and V in the Bushveld and other layered intrusions. Only the latter are present. It is tempting to attribute the absence of komatiite-hosted deposits to the specific character of the ultramafic rocks in Kaapvaal greenstone belts, which are older that the 2.7 Ga komatiites that host deposits in Australia, Canada and Zimbabwe, and are of the less-common “Al-depleted” type. However, a review of mantle melting processes found no obvious connection between the character of the mantle melts and their capacity to form ore deposits. The lack of this type of deposit may be due to differences in the volcanic environment, or it may be fortuitous (the Barberton and other belts are small and could fit into deposit-free parts of the much larger Australian or Canadian belts). Still more puzzling is the absence of Noril'sk-type deposits. The Karoo and older flood basalt sequences appear to contain all the important elements of the volcanic sequences that host the Siberian deposits. It is now recognised that these deposits formed through the segregation of sulfide from magma flowing rapidly through conduits en route from deeper magma chambers to the surface. An exploration approach aimed at understanding the fluid dynamics of such systems seems warranted. Although the Bushveld intrusion has been studied for decades and its deposits are taken as type examples of magmatic mineralisation, the origin of its PGE deposits remains unclear. Opinion is divided on the relative importance of sulfide segregation from magma filling a large chamber at the time of emplacement, and the scavanging of PGE from fluids circulating through cumulates at a late magmatic stage. Answers to these questions may come from studies designed to gain a better understanding of the mechanisms through which the magma chamber filled and solidified.
    Type of Medium: Electronic Resource
    URL: http://dx.doi.org/10.1007/s001260050099
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  • 6
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    A Complex History for the Caribbean Plateau: Petrology, Geochemistry, and Geochronology of the Beata Ridge, South Hispaniola (2000)
    University of Chicago Press
    Details
    Publication Date: 2000-11-01
    Print ISSN: 0022-1376
    Electronic ISSN: 1537-5269
    Topics: Geosciences
    Published by University of Chicago Press
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  • 7
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    Hf and Nd isotope systematics of early Archean komatiites from surface sampling and ICDP drilling in the Barberton Greenstone Belt, South Africa (2015)
    Mineralogical Society of America
    Details
    Publication Date: 2015-11-21
    Description: To constrain the origin of komatiites from the Barberton Greenstone Belt, South Africa, we measured 147 Sm- 143 Nd and 176 Lu- 176 Hf compositions for 18 komatiites from core obtained during the International Continental Drilling Program in the Komati Formation of the Barberton Belt, as well as 33 komatiites from surface outcrops of the Komati, Hooggenoeg, and Weltevreden Formations, these latter for purposes of comparison between core and surface samples. Magmatic clinopyroxene from surface samples near the drill site was also analyzed. For the Lu-Hf isotope system, the Komati Formation core and surface samples including the clinopyroxene define a linear array whose slope corresponds to an age of 3426 ± 16 Ma (MSWD = 118; Hf(T) = +2.2), which is slightly younger than the accepted age of the rocks (3.48 Ga). The Sm-Nd isotope data for the same set of samples likewise fall along a linear array also yielding a younger age of 3339 ± 12 Ma (MSWD = 42; Nd(T) = +2.8). The high MSWD for both isotope systems indicate substantial scatter at variance with normal magmatic processes, likely implying element mobility disturbing even these relatively robust isotopic systems shortly after eruption of the lavas. The average initial Nd and Hf of the core samples at 3.48 Ga are +0.45 and +1.4, respectively, in overall accordance with the positive errorchron intercepts and a depleted mantle source at 3.5 Ga. In contrast, the clinopyroxene and their host rocks have strongly positive Hf(T) of about +5 and negative Nd(T) of about –2. Given the overall scatter of the whole-rock data, the most robust constraint on the composition of the komatiite source comes from the clinopyroxene. Their positive Hf(T) is in line with, though somewhat higher than other results from komatiites from the Komati Formation, but their negative Nd(T) is unexpected in that it indicates a source with long-term low Sm/Nd, which is at odds with its long-term high Lu/Hf. This signature is also found in the trace element compositions of some of the komatiites, such as moderately enriched LREE, negative Hf anomalies, and low Hf/Sm ratios. The origin of these features is uncertain but one possibility is that the discordance between the Hf and Nd isotope systems reflects the presence of deep-sea sediments in the source of some of the Barberton komatiites. The possible presence of a surface component in an ancient deep mantle source has wide-ranging implications for mantle-crust interaction and dynamics in the early Earth and for constraining a minimum age for the onset of plate tectonics.
    Print ISSN: 0003-004X
    Electronic ISSN: 1945-3027
    Topics: Geosciences
    Published by Mineralogical Society of America
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  • 8
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    Evidence from meimechites and other low-degree mantle melts for redox controls on mantle-crust fractionation of platinum-group elements (2006)
    National Academy of Sciences
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    Publication Date: 2006-08-14
    Print ISSN: 0027-8424
    Electronic ISSN: 1091-6490
    Topics: Biology , Medicine , Natural Sciences in General
    Published by National Academy of Sciences
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  • 9
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    The Geochemical Complexity of Kimberlite Rocks and their Olivine Populations: a Reply to the Comment on Cordier et al. (2015) by Andrea Giuliani & Stephen F. Foley (2016)
    Oxford University Press
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    Publication Date: 2016-07-01
    Print ISSN: 0022-3530
    Electronic ISSN: 1460-2415
    Topics: Geosciences
    Published by Oxford University Press
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  • 10
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    A New Model for Barberton Komatiites: Deep Critical Melting with High Melt Retention (2012)
    Oxford University Press
    Details
    Publication Date: 2012-10-20
    Description: The oldest well-preserved komatiites, and the type examples, are found in the Barberton Greenstone Belt in South Africa (3·5–3·3 Ga). All three komatiite types are present, commonly within the same stratigraphic unit. Al-depleted komatiites have low Al/Ti, relatively high concentrations of incompatible elements and depleted heavy rare earth elements (HREE); Al-undepleted komatiites have chondritic Al/Ti and flat HREE patterns; and Al-enriched komatiites have high Al/Ti, low concentrations of incompatible elements, enriched HREE and extremely depleted light rare earth elements. Based on a comprehensive petrological and geochemical study, we propose a new melting model for the formation of these magmas. The basis of the model is the observation, from published experimental studies, that at great depths (~13 GPa) the density of komatiitic liquid is similar to that of solid peridotite. At such depths, melting in a rising mantle plume produces near-neutrally buoyant komatiite melt that does not escape from the residual peridotite. As the source ascends to shallower levels, however, the pressure decreases and the density difference increases, eventually making melt escape possible. Al-depleted komatiites form first at about 13 GPa by equilibrium melting under conditions in which a large proportion of melt (30–40%) was retained in the source and the residue contained a high proportion of garnet (15%). Al-undepleted and Al-enriched komatiites form by fractional melting at intermediate to shallow depths after the escape of a large proportion of melt and after exhaustion of residual garnet. This model reproduces the chemical characteristics of all komatiite types in the Barberton belt and can probably be applied to komatiites in other parts of the world.
    Print ISSN: 0022-3530
    Electronic ISSN: 1460-2415
    Topics: Geosciences
    Published by Oxford University Press
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